WO2008080503A1 - High frequency filter with closed circuit coupling - Google Patents

Abstract

The invention relates to an improved high frequency filter having the following features: the high frequency filter has a transmission behavior with a coupling impedance resonance with at least one null point at a frequency (fs), wherein the null point at the frequency (fs) can be set by specifying and/or preselecting a defined capacitive (12/') and inductive (12/'') coupling between two coaxial resonators (15) directly following one another on a signal path (10).

Description

High frequency filter with blocking circuit coupling

The invention relates to a high-frequency filter with blocking circuit coupling according to the preamble of claim 1.

High frequency filters are used in a wide range.

For example, in the digital mobile radio technology, the mobile subscriber's communication with the base station is handled by transmit-receive antennas provided in the base station. It is desirable to use only a common antenna for the transmit and receive signals.

Transmit and receive signals use different frequency ranges. The antenna used must be capable of transmitting and receiving in both frequency ranges. For the separation of the transmit and receive signals, a suitable frequency filtering is required, which ensures that on the one hand, the transmission signals from the transmitter only to the antenna (and not in the direction of the receiver) and on the other the received signals from the antenna are only forwarded to the receiver.

For this purpose, a pair of high-frequency filters can be used, both of which pass through a specific, namely the respectively desired frequency band (bandpass filter). However, it is also possible to use a pair of high-frequency filters which block a specific, namely the respectively undesired frequency band. One speaks here of band-stop filters. Also possible is the use of a pair of high-frequency filters, consisting of a first filter that passes frequencies below a frequency lying between the transmit and receive band and the overlying areas blocks (low-pass filter), and a second filter, which frequencies below this between the transmit and receive band frequency blocks and passes the higher frequencies. It is then a so-called high-pass filter. Other combinations of the mentioned filter types can be used.

The transmission-Empfangsbandaufsplittung within the base station is performed in this case usually with duplex switches, which have the mentioned task, the transmission-reception path as possible without interference on the common antenna together. The duplexer consists of two interconnected bandpass filters, namely the so-called transmit bandpass (TX bandpass) and the Empfangsband- pass (RX bandpass), with separate connections for the receiving branch, the transmitting branch and the jointly connected antenna are provided.

The bandpasses used inside the duplexer must be On the one hand, therefore, they have the selection (ie the necessary stop attenuation) necessary for the interconnection of the transmitting and receiving bandpass filters (TX / RX) and, on the other hand, they are intended to attenuate the useful signals as little as possible in their respective passband.

The bandpass structures used in duplex switches are predominantly composed of coaxial resonators in the common mobile radio frequency ranges (e.g., GSM / UMTS).

The structure and mode of operation of coaxial resonators are known from the prior art, for example "Ian Hunter: Theory and Design of Microwave Filters", IEEE Electro- magnetic Waves Series, no. 48, 1. Microwave filters, page 197.

In filter theory, bandpasses (so-called Cauer bandpasses) are described which have transmission zeros (so-called blocking poles) in the stopband. This type of filter is very often realized in conjunction with coaxial resonators by so-called cross-coupling. In this case, non-adjacent resonators (ie, in the course of the signal not directly consecutive resonators) within a bandpass structure such capacitive or inductive coupled together that arise due signal splitting with subsequent phase-shifted merge amplitude cancellations (transmission zeros or blocking points) in the transmission characteristic. Such a cross-coupling technique is described, for example, in IEEE Transactions on Microwave Theory and Techniques, Vol. 4, April 2003 "Cross-Coupling in Coaxial Cavity Filters - A Tutorial Overview", J. Brian Thomas, pages 1368-1376. - A -

But the so-called cross-coupling has the disadvantage that the necessary coupling requires resonators that are not adjacent to each other, so are not arranged consecutively. However, this requires filter topologies that make this coupling mechanically possible.

Due to the limited number of suitable pairs of resonators for cross-coupling, only a limited number of reverse poles can therefore be generated.

A generic high-frequency filter with blocking circuit coupling, in particular in the form of a duplexer, can generally be taken as known from WO 2004/100305 A1. It is a high-frequency filter with a plurality of resonators, which are arranged between three terminals, namely between a terminal for a transmitting branch, a connection for the receiving branch and a connection for the common antenna.

According to the generic state of the art, to improve such a duplexer, it is provided that it has at least one resonator pair strongly coupled to one another, wherein the strongly coupled resonators oscillate in the coupled state in two mutually different coupling resonance frequencies which are different from the resonant frequency, which strongly strengthens the two Coupled resonators considered individually in each case in the frequency range between the transmitting and receiving band have or tuned to the resonators.

For example, it is known from WO 02/054527 A2, to provide measures in a coaxial RF filter, whereby a coupling between two adjacent resonators can be set differently. For this purpose, coupling tuning elements, for example, are provided on a separating wall located between two inner conductors of two adjacent coaxial resonators, above which a coupling window is formed to the upper waveguide wall, which can be adjusted in order to change the coupling.

A solution which is basically comparable in this respect has also become known from JP 09-199906 A, which describes the use of adjusting loops between two resonators in order to change the coupling.

According to US Pat. No. 4,216,448, the resonance behavior of the filter is adjusted accordingly by screwing in screws (in the axial extension of the inner conductor) on a coupling path comprising four coaxial resonators. In addition, in this prior publication, a coupling between the first and last resonator on the transmission path (ie not between two on the transmission adjacent successive resonators) provided, by means of an additional coupling window and in the direction of this additional coupling window protruding projections.

Finally, reference is also made to the high-frequency filter according to US Pat. No. 5,389,903 A, which has a T-shaped inner conductor with a cylindrical head which has a larger diameter than the inner conductor carrying the head underneath. This cylindrical head can be eccentric to the shaft of the inner conductor be moved. The resonant frequency of each resonator can be additionally adjusted by screws similar to the aforementioned prior art. The resonators are inductively or capacitively coupled to each other, wherein the inductive or capacitive coupling can be adjusted primarily by varying the ratio between the distance between the shafts and the distance between the heads of the inner conductors. For fine adjustment also serve screws between the individual resonators.

All these Vorveröffentlichungen show what has already been pointed out in the introduction that it is well known to couple individual coaxial resonators with each other and to change the coupling of the Resoantoren and set different.

If, however, blocked areas with transmission zero points (so-called blocking poles) are to be generated, in particular in the construction of band pass filters, then it is necessary to use two capacitive or non-adjacent resonators (ie, on a signal transmission path of non-consecutive resonators) by additional measures inductively coupled to one another in such a way that, due to signal splitting with subsequent phase-shifted combining, amplitude cancellations (transmission zeros or blocking positions) result in the transmission characteristic. This takes place in the context of the so-called coupling technique mentioned in the introduction.

Object of the present invention is in contrast to provide an improved high-frequency filter, the one improved passage and / or blocking effect for predetermined frequencies or frequency ranges, with restrictions on the filter topology should not be possible.

The invention is solved according to the features specified in claim 1. Advantageous embodiments of the invention are specified in the subclaims.

It has proved to be completely surprising that it is possible to generate at least one blocking point (ie at least one blocking pole) at a frequency which is less than + 50% from the center frequency of a bandpass filter, by means of a corresponding coupling of two coaxial resonators immediately adjacent to each other on a signal path.

According to the invention, the improvement over the prior art is achieved essentially by the fact that the high-frequency filter comprising electromagnetically coupled coaxial resonators, with respect to at least one selected coaxial resonator pair whose two coaxial resonators are immediately adjacent to one another in the transmission path, can be specifically preselected and / or presettable Coupling impedance is assigned, which is dimensioned so that due to the combination of capacitive and inductive coupling results in a coupling impedance resonance with a defined stop frequency. Since this type of coupling generates a blocking point in the transmission behavior of the high-frequency filter, it is also referred to below as blocking-circuit coupling.

In other words, it is within the scope of the invention set this blocking circuit coupling, so the blocking frequency, so that it lies on the one hand outside the passband of the RF filter, and on the other hand within the stop band of an RF filter.

Preferably, the blocking frequency can be predefined primarily by changing and / or setting and / or preselecting two variables which essentially influence or determine the blocking frequency. The decisive factor here is that, in addition to a defined inductive resonator coupling, a defined capacitive coupling takes place. The defined inductive coupling may be e.g. be set over the distance of the resonators to be coupled. The required capacitive coupling can be contrasted, for example, realized by an elongated extension at the top of the resonators to be coupled. Even if the change in each of the two variables mentioned above exerts a certain influence on the respective other variable, the desired coupling of adjacent resonators can be set so changed by specifying the inductive and capacitive coupling that the desired attenuation outside of the passband of a RF filter and within a stopband of an RF filter.

Within the scope of the invention, therefore, the following essential advantages can be realized:

• For the first time, adjacent resonators can now be coupled in such a way that blocking positions are generated via them. This offers the significant advantage that in the implementation of high-frequency filters no such limitations in the design of filter Topologies, ie with respect to the arrangement of the coaxial resonators, are present, as in the prior art. In the prior art there was the serious disadvantage that in the so-called "cross-coupling" (ie in the production of a cross coupling), the necessary coupling could not be performed between adjacent resonators. This then required very specific filter topologies to allow coupling between two non-adjacent resonators.

As coupling of two adjacent resonators is possible within the scope of the invention, this basically also offers the option of coupling any number of adjacent pairs of resonators to one another. In the context of the invention, it is even possible to produce n-1 blocking sites in the case of n resonators, ie much more than in the case of a conventional cross-coupling.

In the context of the invention, for the corresponding adjustment of the capacitive coupling, the distance between two inner conductors can be reduced by providing them with radial extensions on their upper side. This can also be used to reduce the overall height of the filter.

The invention will be explained in more detail with reference to drawings. In detail:

Figure 1: The schematic structure of a high-frequency filter in the case of a duplex switch in a schematic basic representation; FIG. 2 shows a schematic top view of a high-frequency filter with a signal path;

Figure 3 is a schematic axial section along the line III-III in Figure 2;

Figure 4 is a Ersat zschaltbild with respect to the embodiment of Figures 2 and 3;

FIG. 5 shows a diagram for the reproduction of the transmission and attenuation behavior of a bandpass filter according to the invention for a duplexer; and

FIGS. 6a to 6f show different views of different settings of a coupling capacitance or coupling inductance.

1 shows a schematic diagram of a high-frequency filter in the form of a duplexer 3, wherein the RF filter 1 comprises three terminals 5, 7 and 9, namely a terminal TX, RX and a terminal for the antenna port AP, so that transmission signals via a first signal path from the transmitting terminal 5 coming from the antenna port AP (from there the common antenna) and vice versa, the received signals from the antenna via the antenna port AP (terminal 9) the receiving terminal 7 can be supplied.

For this purpose, the duplexer 3 comprises in the two signal paths a corresponding bandpass filter 11 or 13, which have the necessary selection (ie stop attenuation), thus From the transmission terminal no signals can get into the reception branch. On the other hand, the pass-bands for the useful signals should be damped as little as possible.

In FIG. 2, for example, a high-frequency filter 1 with a signal path 10 is shown, for example, from a connection 5 to a connection 9, that is, from a transmission connection to an antenna port connection (ie, only the shows a branch of a duplexer) and thereby comprises six coaxial resonators 15.

The coaxial resonators 15 are arranged in a conductive housing 17 with a plurality of resonator chambers 19, where in the embodiment shown in the middle or rather in the central region perpendicular to the housing bottom 17a each have a conductive inner conductor 21 extends - as is apparent from the illustration in Figure 3 - the at a suitable distance below an attachable to the housing 17 electrically conductive housing cover 17b ends.

Each coaxial resonator 15 thus has a circumferential housing wall 17c, wherein along the signal path coupling openings 23, so-called apertures are provided in the respective housing wall 17c, whereby windows are formed, through which the electromagnetic waves can propagate.

Inner conductors 5a and 9a, respectively, which project into the associated resonator chambers 19 and terminate, for example, in a conductive surface element 5b or 9b, are provided in a known manner on the coaxial terminals 5 and 9. about what with the associated inner conductor in the respective coaxial resonators 15 by the capacitance thus formed the coupling of the electric field at the terminal 5 and the corresponding coupling of the electric field at the terminal 9 follows (for example, conversely, the signal received by the antenna via the conductive surface elements 9b in the coupled resonator is coupled on the second signal path, and leads via a second signal path to a connection 7 not shown in detail in Figure 2). Therefore, FIG. 3 shows only a schematic sectional illustration, for example, through a section for the bandpass filter 11 provided for the transmitting branch, whereby the signal path for the second reception branch of the duplex divider not shown in FIG could connect.

With regard to the explained signal path from the terminal 5 to the terminal 9 six coaxial resonators 15.1 to 15.6 are coupled together in this way.

The corresponding equivalent circuit diagram is reproduced in FIG. 4, namely with the signal path 10 from the connection 5 to the connection 9, wherein the six resonators 11 are represented as parallel resonant circuits 111 whose one output is grounded and the opposite output is in the corresponding sequence is connected to the signal path 10. The parallel resonant circuits 24 are characterized in a known manner by a capacitor and an inductance. The distances between the connection points 25 of the individual parallel resonant circuits 24 can also be described by inductances 27, as far as conventional couplings between Coaxial resonators, so not to the below-explained coupling of the invention. As far as a coupling according to the invention comes into play, the connection between two mutually parallel adjacent parallel resonant circuits can not be described by an inductive coupling, but by a blocking circuit coupling in the form of a parallel resonant circuit with a capacitance and an inductance, as shown in Figure 4 , Between the first and fifth coaxial resonators 15.1 and 15.4, as in the prior art, a capacitive cross-coupling using a capacitor C is additionally realized (see FIG. 2 and FIG. 4).

According to this equivalent circuit diagram according to FIG. 4, it is shown that a coupling according to the invention is realized between the first and the second coaxial resonators 15.1 and 15.2 as well as between the second and third coaxial resonators 15.2 and 15.3 as well as the third and fourth coaxial resonators 15.3 and 15.4. In addition, in the embodiment shown, a conventional coupling (cross-coupling) between the first and the fifth coaxial resonators 15.1 and 15.5 is shown, which is also discussed below.

From the side view according to FIG. 3, it can be seen that, for coupling the immediately adjacent resonators 15.1 and 15.2, which are directly consecutive in the signal run, the associated inner conductors are provided in their connecting direction with radially protruding inner conductor sections 21a facing each other. As a result, the clear distance 121 between the two inner conductors 21 is adjusted so that over gives a desired capacitive coupling.

This capacitive coupling is shown, for example, between inner conductor sections 21a on the two inner conductors 21 of the two first coaxial resonators 15.1 and 15.2 in FIG. 3, by correspondingly drawn E-field vectors 121 '(FIG. 2).

In addition, an inductive coupling through an H-field line 121 "is also shown in FIG. 3 for the two first resonators 15.1 and 15.2

Distance 321 between the two inner conductors 21 (without

Considering the aforementioned radially projecting inner conductor sections 21a), the inductive coupling is ultimately preselected and / or adjusted accordingly.

However, the inductive coupling can be preset or selected differently by other alternative or supplementary, ie additional measures. In general, it is noted that the coupling capacitances and coupling inductances necessary for setting the blocking circuit coupling can be set by known coupling setup variants. Thus, for example, the coupling diaphragms (ie the passage openings between two adjacent coaxial resonators in the height and / or width can be set differently, whereby the degree of coupling changes). Likewise, coupling pins can be provided between the resonators, coupling loops or coupling webs. The coupling webs would extend, for example, in a partial height between two inner conductors, ie also extend parallel to the inner conductors (preferably perpendicular to the bottom wall) and thereby be electrically connected to the bottom of the coupling resonators. The Coupling loops can be electrically and mechanically connected in the manner of an inverted U-bracket between two inner conductors on the ground. It is also possible for a coupling loop to be positioned in a vertical orientation (ie lying in a vertical plane) or in a plane slightly inclined thereto via a vertical axis of rotation with respect to the ground and can thereby be rotated in the circumferential direction. The larger the area penetrated by the magnetic surfaces, the greater the coupling effect. The mentioned effects can also be used in combination or parts thereof in combination in order to implement and implement the desired coupling setting options accordingly.

The adjustment options mentioned above are reproduced, for example, with reference to FIG. 6a using electrically conductive coupling pins 301, wherein a pin 301 provided, for example, in the upper cover 17b for changing the coupling capacitance between two inner conductors 21 at different altitudes, that is, different distances into the interior between two resonators can be screwed, wherein in FIG. 6a, an electrically conductive coupling pin 302 which is screwed in or positioned in the bottom 17a is arranged, the height and diameter of which contribute to the change in the coupling inductance. On the basis of Figure 6b is shown in plan view that along the connecting line of two adjacent inner conductor 21 is provided from the ground uplifting web, which extends there against the height of the inner nenleiter in a partial height. This is a so-called coupling web 307. This coupling web 307 is electrically connected to the bottom 17a of the housing 17 of the RF filter. According to a further exemplary embodiment according to FIG. 6c in a top view and according to FIG. 6d in a vertical section, it is shown that, for example, a first window opening 303 (coupling diaphragm) between the coaxial resonator 15.1 and 15.2 is significantly reduced and, on the other hand, a further coupling diaphragm 303 between the resonator 15.2 and 15.3 becomes clear is enlarged, so that the coupling aperture in any case has a greater width parallel to the bottom or top surface.

In the exemplary embodiment according to FIG. 6e, a coupling loop 305 for changing the coupling inductance, which is positioned in the bottom in the manner of an inverted "U", is shown. Alternatively, the use of a coupling loop is shown with reference to FIG. 6f, which can be rotated about its vertical axis 305 ', so that the magnetic field strength passing through the loop changes, whereby the coupling inductance can be changed and set differently.

In general, it is noted that the various possibilities for generating a desired capacitive, as well as a desired inductive coupling can be combined in any way, rather even all the above variants can be applied cumulatively. There are no restrictions in this respect.

Due to the different design of the coaxial resonators 15 with the described deviating resonator shape, the desired blocking position can be generated with a defined blocking frequency outside the passband of an HF filter. It is crucial that in addition to the aforementioned defined inductive resonator coupling a defined capacitive coupling is present. As mentioned, the aforementioned inductive coupling can be adjusted by the distance 321 of the resonators to be coupled (position of the inner conductor 21 of the relevant resonator), whereas the capacitive coupling is adjusted via the clear distance 121 between two adjacent inner conductors 21 of two adjacent resonators, the size of which can be predetermined by the clear distance of the mentioned elongated (radially protruding) inner conductor extensions 21.

In the exemplary embodiment shown, in addition to the coupling between the first and second coaxial resonators 15.1 and 15.2, a further directly subsequent coupling between the second and third coaxial resonators 15.2 and 15.3 is realized.

In contrast to the first inner conductor 21 of the first Koaxialresonators 15.1, which is formed in cross-sectional view in the manner of an inverted L, now the second inner conductor of the second Koaxialresonators 15.2 is formed in the manner of a T-shaped, namely with another, usually parallel to the ground and thus transversely or radially to the inner conductor protruding, opposite Innenleitererwei- sion 21 a. The third inner conductor 21 of the third coaxial resonator 15.3 to be coupled therewith could also be provided with a corresponding inner conductor extension 21a, the distance between these two adjacent inner conductor extensions 21a being much greater than the distance between the first and second coaxial resonators. In the example of the coupling of the second and third coaxial resonator, an additional bridging member 221 is further provided for this purpose, which is held and positioned in isolation with respect to the housing. There- there are two pitch gaps 121a and 121b in which the electric field vectors propagate through air. The sum distance formed from the two individual distances 121a and 121b gives the size which is decisive for the specification of the desired defined capacitance coupling.

Finally, it can also be seen from the top view according to FIG. 2 that the additional inner conductor 21 does not see two inner conductor extensions 180 'opposite each other (as the second inner conductor 21 of the second coaxial resonator 15.2 does) due to the further coupling between the third and fourth coaxial resonators 15.3 and 15.4 ), but has two inner conductor extensions 21a, which are arranged at a 90 ° angle to each other, namely according to the signal path of the electromagnetic waves angled at 90 ° .The fact that the two inner conductors 21 are positioned more densely with respect to the second and third resonators 15.2 and 15.3 results from the illustration of Figure 2 in plan view.

If the explained signal path represents, for example, the one signal path of a duplexer, then a bandpass filter can be realized, as reproduced in FIG. 4, with one or more blocking frequencies f _s , ie one or more so-called blocking poles. This transmission characteristic shows that, in accordance with the number of coaxial resonators coupled within the scope of the invention, the plurality of blocking poles (blocking frequencies) can be generated such that these blocking frequencies lie, for example, in the passband (frequency range) of an adjacent bandpass filter which is offset. In the exemplary embodiment shown, another coupling according to the invention may also be implemented at any other arbitrary point, that is to say, for example, between the fourth and fifth and / or fifth and sixth coaxial resonators. In general, in n-coaxial resonators, therefore, five, namely n-1 coupling impedances can be dimensioned such that a coupling impedance results in each case with a defined frequency f _s due to the communication of capacitive and inductive coupling, ie a blocking point by the type of coupling in the transmission behavior of the high-frequency filter at the at least one or more mutually offset frequencies f _sl , f _s2 , f _s3 , etc. to f _Sn results, which may be referred to as blocking circuit coupling.

In the exemplary embodiment shown, a conventional coupling is additionally realized, which can also be additionally provided in the case of the HF filter according to the invention. This conventional coupling (cross-coupling) is also shown in the equivalent circuit diagram according to FIG. 4, namely there via the connecting path 131 with the capacitor C provided there.

2, a coupling element 31 is shown, which acts between the first and fifth coaxial resonators and is usually formed by an electrically conductive coupling element projecting into the respective cavity of the associated resonator and having a "bone-shaped" side view Generated by its enlarged opposite conclusion with the associated inner conductor in the respective coaxial resonator capacitive coupling. This is also included in the equivalent circuit diagram. characterized, namely by the capacitive coupling path 131.

In contrast, a blocking circuit coupling 35 with a parallel-connected inductance and a capacitance is realized within the scope of the invention, as is also shown in the equivalent circuit diagram according to FIG.

Finally, reference is made to FIG. 5, in which a diagram of the bandpass behavior of a bandpass filter 11 for a transmission branch and for a bandpass filter 13 for a reception branch (in dashed lines) is reproduced. This shows the number of blocking poles f _{RS /} f _τs , depending on the number of blocking circuit _couplings used. In FIG. 5, the increasing frequency F is reproduced on the X-axis and the damping D on the Y-axis.

For a bandpass filter is also shown how the attenuation would be, if not the inventive

Coupling would be realized (dash-dotted curve).

In the bandpass filter according to the invention, the at least one or more blocking poles can be laid so that they lie, for example, in a frequency range of an adjacent bandpass offset from the passband of the relevant bandpass. In any case, sufficient advantages according to the invention can still be realized if the one or more blocking poles are arranged, in whole or in part, at least in such a way that they lie outside the actual passband of the bandpass filter in a frequency range which differs from the center frequency of the relevant bandpass filter. less than ± 50%, in particular less than ± 40%, ±

30%, ± 20% and especially less than ± 10%.

In the case of two mutually offset Bandpassdurchlaßfrequenzbereiche, as used in the most common case in a duplex switch, the advantages of the invention can still be realized to a sufficient extent, if at least one or more of the Sperrpole (blocking points) of a respective bandpass filter Considered by appropriate choice of suitable coupling capacitances and coupling inductances is so laid or be that this at least one Sperrpol in a frequency range is generated, not more than five times the duplex spacing (ie the frequency center distance of two adjacent band passes) of the center frequency the relevant bandpass away. Preferably, therefore, the blocking poles, viewed from a bandpass filter, should be arranged outside the passband of the bandpass filter such that the blocking poles are not more than five times, in particular not more than four times, three times, twice or even less than the duplex spacing (ie the second frequency spacing second) neighboring bandpasses).

Regardless, of course, one or more of the blocking poles can also be positioned in a frequency range of the adjacent bandpass.

Finally, it is noted that, with appropriate choice of the inductive or the capacitive coupling can be determined whether the respective Sperrpol below a Bandpass filter or above a bandpass filter (ie with the bandpass filter lower frequency or higher frequency) is formed. This is achieved by selecting the coupling capacitance and coupling inductance of the trap coupling so that the resulting resonant frequency is either below or above the bandpass passband as needed.

Claims

Claims:

1. High-frequency filter, in particular for a duplexer, with a plurality of electromagnetically coupled coaxial resonators (15) having the following features,

the high-frequency filter has a coupling-impedance-dependent transmission characteristic, characterized by the following further features:

- the coupling impedance-dependent transmission behavior of the high-frequency filter comprising at least one locking point at a frequency (f _s),

the blocking point lies outside the passband of the high-frequency filter and within the stop band of the high-frequency filter, and

- Two on a signal path (10) immediately successive Koaxialresonatoren (15) have for this purpose a coupling capacitance and a coupling inductance such that the at least one locking point at a frequency (f _s ) is not greater than ± 20 of the center frequency of the bandpass filter % is removed.

2. High-frequency filter according to claim 1, marked thereby characterized, that the locking point at the frequency (f _s) by default and / or preselection of a coupling capacitance and mutual inductance between the two in the signal path (10) directly consecutive coaxial resonators (15) is adjustable ,

3. High-frequency filter according to claim 1 or 2, characterized in that the at least one coupling capacitance and the at least one coupling inductance are selected such that the at least one blocking point is at a frequency (f _s ) which does not exceed the center frequency of the bandpass filter ± 10% from the frequency of the bandpass filter.

4. High-frequency filter according to at least one of claims 1 to 3, characterized in that n-coaxial resonators

(15) are coupled together on a signal path (10), wherein more than one and less than n-1 blocking circuit couplings are provided.

5. High-frequency filter according to one of claims 1 to 4, characterized in that the high-frequency filter (1) comprises at least two bandpass filters, wherein the per bandpass filter at least one pair of immediately adjacent in the signal path, adjacent coaxial resonators (15) a blocking circuit coupling with a frequency ( f _s ) such that the blocking point lies outside the passband of the bandpass filter in question, wherein preferably at least one blocking position lies in the passband of the respective other bandpass filter.

6. High-frequency filter according to claim 5, characterized in that the at least two bandpass filters are part of a duplexer (3).

7. high-frequency filter according to claim 5 or 6, characterized in that the at least one locking point or preferably the plurality of locking points from the center frequency of a bandpass filter from view no further than the fivefold of the duplex spacing, ie the center frequency spacing of the two bandpass filters of a duplex line are removed, preferably less than four times, three times, two times or especially the simple one of the duplex spacing.

8. High-frequency filter according to one of claims 1 to 7, characterized in that several on a signal path (10) immediately successive Koaxialresonator- pairs to produce a plurality of defined Sperrkreiskopplungen with defined frequencies (f _sl> f _s2, f _s3, ...) are provided, wherein the blocking frequencies are at least partially different or at least partially the same.

9. High-frequency filter according to claim 8, characterized in that the capacitive and the inductive coupling can be predetermined such that the at least one frequency (f _s ) of the associated blocking circuit coupling has a lower frequency or a higher frequency than the bandpass filter.

10. High-frequency filter according to one of claims 1 to 9, characterized in that the degree of capacitive coupling between two adjacent inner conductors (21) of two adjacent Koaxialresonatoren (15) by radially in the direction of each coupled adjacent inner conductor (21) with radially projecting inner conductor extension ( 21a) and thus by appropriate specification of the clear distance (121, 121a, 121b) between two corresponding inner conductors (21) and associated Innenleitererweiterun- conditions (21a) can be predetermined.

11. High-frequency filter according to claim 10, characterized indicates that the inner conductor extension (21a) is formed transversely and preferably perpendicular to the axial extent of an associated inner conductor (21) in the upper end region of the inner conductor (21).

12. High-frequency filter according to claim 10 or 11, characterized in that the inner conductor (21) is formed with a corresponding inner conductor extension (21 a) in the manner of an inverted L-shaped.

13. High-frequency filter according to claim 11, characterized in that an inner conductor (21) with a in the signal path (10) preceding and subsequent coaxial resonator (15) is coupled to produce two blocking circuit couplings, including the associated inner conductor (21) both in the direction of the preceding and the subsequent coupled coaxial resonator (15) is provided with an inner conductor extension (21 a).

14. High-frequency filter according to claim 13, characterized in that the inner conductor (21) with the associated inner conductor extension (21 a) is T-shaped.

15. High-frequency filter according to one of claims 1 to 14, characterized in that between two inner conductors (21), preferably in the upper free end region, a free path between the two inner conductors (21) shortening, electrically conductive bridge member (221) is provided which is arranged at a distance from the respective inner conductors (21) or the inner conductor extensions (21a) formed there, whereby a predefinable sum distance, consisting of the two clear spacings (121a, 121b) between the bridge member (221 ) and the adjacent inner conductors (21) or the associated inner conductor extensions (21a), can be predetermined, whereby the capacitive coupling is adjustable.

16. High-frequency filter according to one of claims 1 to 15, characterized in that from the opposite side of the housing (cover 17b) of the housing (17) of the coaxial resonator (15) a coupling pin (301) between two adjacent coaxial resonators (15) in the Resonatorinnenraum changed Setting the coupling capacity protrudes.

17. High-frequency filter according to one of claims 1 to 16, characterized in that the inductive coupling between two adjacent coaxial resonators (15) by specifying the distance (321) between the position of the inner conductor (21) and / or from the housing bottom or the housing cover (17a, 17b) transversely extending inner conductor (21) is vorgeb- and / or changeable.

18. High-frequency filter according to one of claims 1 to 17, characterized in that the inductive coupling between two adjacent coaxial resonators (15) by a different size of a coupling window (303) or a coupling diaphragm (303) between two adjacent coaxial alresonatoren vorgeb- and / or changeable.

19. High-frequency filter according to one of claims 1 to 18, characterized in that the inductive coupling between two adjacent coaxial resonators (15) by coupling pins (302) vorgeb- and / or changeable, on the same side of the housing (17) as the Inner conductor (21) on the housing (17, 17a) are positioned.

20. High-frequency filter according to one of claims 1 to 19, characterized in that the inductive coupling between two adjacent coaxial resonators (15) by a coupling web (307) vorgeb- and / or changeable, extending between two inner conductors (21) in a partial height extends relative to the inner conductor and preferably on the same housing wall (housing bottom 17a) is positioned, on which the inner conductor (21) are electrically and mechanically connected and held.

21. High-frequency filter according to one of claims 1 to 20, characterized in that the inductive coupling between two adjacent coaxial resonators (15) by at least one coupling loop (305) vorgeb- and / or ver¬ changeable, between two inner conductors (21) of two adjacent coaxial resonators (15) is arranged, wherein the coupling loop (305) for changing the coupling inductance is bendable and / or rotatable.

22. High-frequency filter according to one of claims 1 to 21, characterized in that the high-frequency filter in addition to one or more Sperrkreiskopplungen one or more capacitive cross-coupling (cross-coupling).